Fold-type data processing apparatus having a hinge

ABSTRACT

A fold-type cellular phone has a top unit, a bottom unit and a hinge coupling together the top unit and the bottom unit while allowing the top unit to turn and swivel with respect to the bottom unit. The top unit is first unfolded from a first folded position to an attitude angle of 160 to 170 degrees, and swiveled by 180 degrees to be folded onto the bottom unit in a second folded position at an attitude angle of 180 degrees. The swivel movement of the top unit causes a cam assembly to turn the top unit from the attitude angle of 160–170 degrees to an attitude angle of 180 degrees in the second folded position, thereby allowing the top unit to assume a suitable attitude with respect to the bottom unit.

BACKGROUND OF THE INVENTION

(a) Field of the Invention

The present invention relates to a fold-type data processing apparatushaving a hinge and, more particularly, to a fold-type data processingapparatus, such as cellular phone, hand-held personal computer andportable data assistant, having a hinge mechanism therein.

(b) Description of the Related Art

Recent cellular phones have a variety of functions in addition to theconventional telephone function, such as internet browser, e-mail andschedule management functions. Thus, the cellular phone may be referredto as a portable data processing apparatus or personal data assistant.This fact necessitates the cellular phone to have a larger-size displayunit to display thereon a larger amount of image information includingfigures as well as characters and numerals.

To solve a trade-off between a larger-size screen for the display unitand a smaller weight of the cellular phone as encountered in theconventional technique, a fold-type structure is increasingly used forthe chassis of the cellular phone. In general, the fold-type structureof the cellular phone is such that the chassis of the cellular phone hasa top chassis section (top unit) and a bottom chassis section (bottomunit) coupled together via a hinge, and the display unit and thekeyboard are exposed for operation by unfolding the top chassis sectionwith respect to the bottom chassis section. A fold-type structure hasbeen proposed wherein the screen of the display unit is exposed in afolded position of the chassis for allowing the cellular phone tofunction as an e-mail or browser unit without switch-ON of the telephonefunction.

JP Patent Publication 11(1999)-215218 (first publication) describes afold-type structure of the cellular phone wherein the top chassissection mounting thereon a display unit and the bottom chassis sectionmounting thereon a keyboard are coupled together via a ball joint forallowing swiveling of the top chassis section in any direction withrespect to the bottom chassis section.

In the fold-type structure described in the first publication, it isdifficult to fix the relative attitude of the top chassis section withrespect to the bottom chassis section during an unfolded positionthereof, because both the sections are coupled via the ball joint. Thisrather hinders the user from handling the cellular phone comfortably.

JP Patent Publication 2002-158758 (second publication) describes afold-type structure of the cellular phone, wherein the top chassissection mounting thereon a display unit and the bottom chassis sectionmounting thereon a keyboard are coupled together for allowing swivelingof the top chassis section with respect to the bottom chassis section sothat the operating planes of the display unit and the keyboard aredirected in the same direction.

In the fold-type structure described in the second publication, if oneof the chassis sections is swiveled with respect to the other, withsurface portions of both the chassis sections being in contact with oneanother, the contacted surface portions may have mechanical damagesthereon. This problem is common to the fold-type structure described inthe first publication.

SUMMARY OF THE INVENTION

It is an object of the present invention to provide a fold-type dataprocessing apparatus having an improved hinge mechanism therein, whereinthe relative attitude between two chassis sections is controlled withease.

It is another object of the present invention to provide a fold-typedata processing apparatus having an improved hinge mechanism, whereintwo chassis sections are prohibited from swiveling with respect to oneanother when the surface portions of two chassis sections are in contactwith one another.

It is a further object of the present invention to provide such animproved hinge mechanism.

The present invention provides a fold-type data processing apparatusincluding a first unit, a second unit and a hinge mechanism for couplingtogether the first unit and the second unit and allowing the second unitto turn and swivel with respect to the first unit via the hingemechanism, the hinge mechanism including: a shaft having a first axisand mounting thereon the second unit for allowing the second unit to beturned around the first axis; a swiveling member fixed onto the firstunit and allowing the shaft and the second unit to swivel with respectto the first unit around a second axis perpendicular to the first axis;at least one projection member fixed onto the shaft; and a controlmember fixed onto the first unit and having a side wall, at least aportion of the side wall having a slanted surface, wherein theprojection member abuts the side wall to restrict a movement of thesecond unit.

The present invention also provides a hinge mechanism including: a base;a shaft having a first axis; a first support member for supporting theshaft and allowing the shaft to rotate around the first axis; a secondsupport member for supporting the first support member with respect tothe base and allowing the first support member and the shaft to swivelwith respect to the base around a second axis perpendicular to the firstaxis; and a cam assembly for converting a swivel movement of the shaftwith respect to the base to a rotational movement of the shaft.

In accordance with the fold-type data processing apparatus of thepresent invention, the attitude of the second unit with respect to thefirst unit is controlled by the rotational movement of the shaftconverted from the swivel movement of the second unit while using theprojection member on the shaft and the control member fixed onto thefirst unit. Thus, a desired attitude of the second unit can be obtainedby the swivel movement of the second unit.

In accordance with the hinge mechanism of the present invention, the camassembly converts the swivel movement of the shaft to the rotationalmovement of the shaft, whereby a desired rotational movement can beobtained simply by swiveling the rotational shaft. The above and otherobjects, features and advantages of the present invention will be moreapparent from the following description, referring to the accompanyingdrawings.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1A is a top plan view of a cellular phone having top and bottomchassis sections in a first folded position of chassis, and shown as afold-type data processing apparatus according to a first embodiment ofthe present invention.

FIG. 1B is a top plan view of the cellular phone of FIG. 1A in anunfolded position of the chassis.

FIG. 1C is a top plan view of the cellular phone of FIG. 1A in aswiveled position wherein the top chassis section is swiveled withrespect to the bottom chassis section from the unfolded position of FIG.1B.

FIG. 1D is a top plan view of the cellular phone of FIG. 1A in a secondfolded position of the chassis.

FIG. 2 is a perspective view of the hinge used in the cellular phone ofFIG. 1A.

FIGS. 3A and 3B are a schematic top plan view and side view,respectively, of the hinge of FIG. 2.

FIG. 4 is a sectional view of the torque generator disposed in the hingeof FIG. 2.

FIGS. 5A and 5B are a perspective front view and rear view,respectively, of the hinge of FIG. 2 in an unfolded position of thechassis.

FIG. 6A is a perspective side view of the hinge of FIG. 2 in a 90-degreeswiveled position of the chassis, FIG. 6B is a top plan view of thecellular phone in this swiveled position, and FIG. 6C is a sectionalview taken along line VI—VI in FIG. 6B.

FIG. 7A is a top plan view of a control member for controlling theattitude angle between the chassis sections.

FIG. 7B is a schematic side view of the hinge in the folded position.

FIG. 7C is a schematic side view of the hinge of FIG. 7B in aslightly-unfolded position.

FIG. 7D is a schematic side view of the hinge in the unfolded position.

FIG. 8A is a top plan view of a control member for controlling theattitude angle between the chassis sections of the hinge in a cellularphone shown as a fold-type data processing apparatus according to asecond embodiment of the present invention.

FIG. 8B is a schematic side view of the hinge in the first foldedposition of the hinge in the second embodiment.

FIG. 8C is a schematic side view of the hinge in an unfolded positionthereof in the second embodiment.

FIG. 8D is a schematic side view of the hinge in the second foldedposition thereof in the second embodiment.

FIG. 9A is a top plan view of a control member for controlling theattitude angle between the chassis sections of the hinge in a cellularphone shown as a fold-type data processing apparatus according to athird embodiment of the present invention.

FIG. 9B is a schematic side view of the hinge in the first foldedposition thereof in the third embodiment.

FIG. 9C is a schematic side view of the hinge in an unfolded positionthereof in the third embodiment.

FIG. 9D is a schematic side view of the hinge in the second foldedposition thereof in the third embodiment.

FIG. 10A is a top plan view of a control member for controlling theattitude angle between the chassis sections of the hinge in a cellularphone shown as a fold-type data processing apparatus according to afourth embodiment of the present invention.

FIG. 10B is a schematic side view of the hinge in the first foldedposition of the hinge in the fourth embodiment.

FIG. 10C is a schematic side view of the hinge in an unfolded positionthereof in the fourth embodiment.

FIG. 10D is a schematic side view of the hinge in the second foldedposition thereof in the fourth embodiment.

FIG. 11A is a top plan view of the cellular phone of the fourthembodiment in the swiveled position of the top chassis section, and FIG.11B is a sectional view taken along line XI—XI in FIG. 11A.

FIG. 12 is a schematic diagram exemplifying the abutment between theprojections on the shaft and the control member in the fold-type dataprocessing apparatus according to the embodiment of the presentinvention.

PREFERRED EMBODIMENTS OF THE INVENTION

Now, the present invention is more specifically described with referenceto accompanying drawings, wherein similar constituent elements aredesignated by similar reference numerals. It is to be noted that thepresent invention is an improvement from the inventions described in JPPatent Applications 2001-30395, 2002-107405 and 2002-189488 whichdescribe improvements of operational functions and hinges of cellularphones, and is devised based especially on the invention described in2002-107405.

First Embodiment

Referring to FIGS. 1A to 1D, there are shown a plurality of attitudes ofthe chassis of a cellular phone, generally designated by numeral 10 andshown as a fold-type data processing apparatus according to a firstembodiment of the present invention. More specifically, FIGS. 1A to 1Dshow a first folded position (first closed position) of a top chassissection (top unit) of the cellular phone 10, wherein the top unit isfolded onto a bottom chassis section (bottom unit), an unfolded position(open position) wherein the top unit 200 is unfolded from the bottomunit 100 by turning the top unit 200 in the direction D1 from the firstfolded position of FIG. 1A via a hinge 300 fixed onto the bottom unit100, a swiveled position wherein the top unit 200 is swiveled by 90degrees in the direction D2 via the hinge 300 from the unfolded positionof FIG. 1B, and a second folded position wherein the top unit 200 isfurther swiveled by 90 degrees in the direction D2 via the hinge 300from the swiveled position of FIG. 1C, respectively.

The hinge 300 in the cellular phone 10 is of a two-axial structure andcouples the top unit 200 and the bottom unit 100 together so that thetop unit 200 can be turned and swiveled via the hinge 300 with respectto the bottom unit 100. The top unit 200 can be turned in the directionD1 via the hinge 300 for closing and exposing the surface of the bottomunit 100, and can be swiveled in the direction D2 via the hinge 300 withrespect to the bottom unit 100 from the unfolded position. The bottomunit 100 mounts a keyboard 101 and a microphone 102 on the main surfacethereof, whereas the top unit 200 mounts an elongate display unit 201and a speaker 202 on the main surface thereof.

In the first folded position of FIG. 1A, the main surfaces of both thetop and bottom units 200 and 100 oppose one another, whereby thekeyboard 101 and the display unit 201 are protected against an externalforce by both the top and bottom units 200 and 100, respectively. In thefirst folded position, the hinge 300 restricts the swiveling of the topunit 200 in the direction D2. In a slightly unfolded position whereinthe top unit 200 is slightly turned in the direction D1 with respect tothe bottom unit 100 via the hinge 300, the top unit 200 is released fromthe restriction of the swiveling in the direction D2 by the hinge 300.

In the unfolded position of FIG. 1B wherein the top unit 200 is turnedin the direction D1, the keyboard 101, display unit 201, microphone 102and speaker 202 are exposed from the chassis, thereby allowing operationof the cellular phone 10 for dialing a call number, key input, speakingetc. The hinge 300 restricts the attitude angle of the top unit 200 withrespect to the bottom unit 100 within a range between 160 degrees and170 degrees in the direction D1 in the unfolded position of FIG. 1B,whereas the hinge 300 releases the restriction of the swiveling of thetop unit 200 in the direction D2 in the unfolded position whereby thetop unit 200 can be swiveled for any desired angle. When the top unit200 is swiveled in the direction D2, the angle between the main surfaceof the top unit 200 may be maintained within the range between 160degrees and 170 degrees with respect to the main surface of the bottomunit 100. In an alternative, the angle between the main surfaces may beincreased with the increase of the swiveled angle of the top unit 200.

In the swiveled position of FIG. 1C wherein the top unit 200 is swiveledby 90 degrees in the direction D2 from the unfolded position of FIG. 1B,the top unit 200 may be temporarily fixed by a snapping engagement atthe 90-degree swiveled position. In such a case, the angle between themain surfaces of both the top unit 200 and the bottom unit 100 may bemaintained at 160 to 170 degrees or may be increased up to 180 degreesand fixed thereto.

In the second folded position of FIG. 1D wherein the top unit 200 isfurther swiveled by 90 degrees via the hinge 300 in the direction D2from the position of FIG. 1C, the top unit 200 is fixed onto the bottomunit 100 with the display unit 201 being exposed from the chassis at thetop thereof. The hinge 300 also restricts the swiveling of the top unit200 in the second folded position, whereas the hinge 300 allowsswiveling of the top unit 200 by 360 degrees in the direction D2 in aslightly unfolded position wherein the top unit 200 is slightly turnedin the direction D1 with respect to the bottom unit 100 from the secondfolded position.

Now the two-axial structure of the hinge 300 will be detailedhereinafter.

Referring to FIG. 2, the hinge 300 includes a base plate 301 providedwith a pair of brackets 301 a and 301 b at both the ends thereof, whichare fixed onto the bottom unit 100 for fixing the hinge 300. The hinge300 includes a torque generator 302 having a cylindrical post standingvertically at the center of the base plate 301 and mounting, at the topthereof, a control member (or control projection) 303 and a couplingbracket 304 for controlling the attitude angle between the top unit 200and the bottom unit 100 during the swivel movement of the top unit 200.

The control member 303 is fixed onto a fixed shaft (not shown in thedrawing) of the torque generator 302 which is fixed onto the base plate301. The coupling bracket 304 is of a U-character shape, and has abottom plate fixed onto the cylindrical post of the torque generator 302and a pair of side plates 304 a and 304 b extending from both the endsof the bottom plate in the direction perpendicular to the bottom plate.The control member 303 penetrates the bottom plate of the couplingbracket 304 for allowing swiveling of the coupling bracket 304 withrespect to the control member 303 in the direction D2 around the fixedshaft of the cylindrical post of the torque generator 302. The torquegenerator 302 generates a torque in the direction D2 between the fixedshaft and the cylindrical post of the torque generator 302, the torqueproviding a snapping engagement or slight temporary engagement duringrotation of the cylindrical post, as will be detailed later.

A shaft 305 rotatably penetrates the side plates 304 a and 304 b of thecoupling bracket 304. The portion of the shaft 305 sandwiched betweenthe side plates 304 a and 304 b of the coupling bracket 304 has a pairof projections 306 a and 306 b at the central position thereof, therebyallowing the projections 306 a and 306 b to abut the control member 303.The projections 306 a and 306 b function as swivel stoppers for stoppingthe swiveling of the shaft 305 by the abutment to the control member303. The provision of the projections 306 a and 306 b increases thedesign choice for the position and configuration of the control member303.

Referring to FIGS. 3A and 3B, the control member 303 is of a truncatedcone and has a slot 303 a on the slanted side wall thereof. The slot 303a has vertical side walls and receives therein the tip of projection 306a or 306 b.

FIG. 3B shows the hinge 300 in the folded position of FIG. 1A whereinthe top unit 200 is folded onto the bottom unit 100. In the foldedposition, the first projection 306 a on the shaft 305 is received in theslot 303 a of the control member 303, whereby the top unit 200 cannotswivel in the direction D2.

L-shaped brackets 307 and 308 are provided on both the ends of the shaft305, and fixed onto the top unit 200. Folding/unfolding torquegenerators 309 and 310 are fixed onto both the side surfaces 304 a and304 b, respectively, of the coupling bracket 304, allowing the shaft 305to penetrate therethrough, whereby a turning torque is generated in thedirection D1 as in the case of the swiveling torque generator 302. Thisturning torque also generates a snapping engagement during folding andunfolding the top unit 200.

Referring to FIG. 4, there is shown a schematic configuration of theswiveling torque generator 302. The swiveling torque generator 302includes a hollow cylindrical post 320, and a cylindrical fixed shaft321, a pair of rotation cams 322 and 323, a pair of fixed cams 324 and325 and a coil spring 326 which are received in the hollow cylindricalpost 302. The fixed shaft 321 penetrates the top plate and bottom plateof the cylindrical post 320 for allowing rotation thereof, has a bottomend fixed onto the base plate 301 and a top end on which the controlmember 303 is fixed.

The pair of rotation cams 322 and 323 are respectively fixed onto theinner surfaces of the top plate and the bottom plate of the cylindricalpost 320. The fixed shaft 321 penetrates the pair of rotation cams 322and 323 for allowing rotation thereof. The pair of fixed cams 324 and325 have configurations matched with the shapes of the rotation cams 322and 323, respectively, allowing the fixed shaft 321 to penetratetherethrough. The fixed cams 324 and 325 are fixed onto the fixed shaft321 in the rotational direction by a suitable means and allowed to movein the axial direction of the fixed shaft 321. The coil spring 326 issandwiched between the fixed cams 324 and 325, thereby urging the fixedcams 324 and 325 in the opposite directions.

A specific combination of the rotation cam 322 and the fixed cam 324 aswell as a specific combination of the rotation cam 323 and the fixed cam325 is employed wherein the convex and concave positions of the rotationcam 322 or 323 having a periodic structure are suitably combined withthe concave and convex positions of the fixed cam 324 or 325 with aperiod of 90 degrees. This combination generates a pull-in torque topull the top unit 200 toward each of the swivel positions of the topunit 200 shown in FIGS. 1A to 1D in the vicinity of the each of theswivel positions. It is to be noted that by slightly deviating the phaseof the concave and convex positions between the rotation cam and thefixed cam, a rattling torque can be avoided during generation of thesnapping engagement.

The turning torque generators 309 and 310 by which the folding/unfoldingtorque is generated during folding and unfolding the top unit 200 havebasic configurations similar to those of FIG. 4. It is to be notedhowever that the pull-in torque is generated by the cam assembly in thevicinity of attitude angles of zero and 180 degrees between the top unit200 and the bottom unit 100. In particular, a pull-in torque should begenerated at a position around an attitude angle of 160 to 170 degrees,such as the position illustrated in FIG. 1B, to pull in the top unit 200toward an attitude angle of 180 degrees.

As described above, FIGS. 2, 3A and 3B show the hinge at the foldedposition of the chassis. In the folded position, one of the projections306 a and 306 b, i.e., the first projection 306 a, on the shaft 305 isreceived in the slot 303 a of the control member 303, whereby the topunit 200 cannot be swiveled in the direction D2.

FIG. 5A shows the front view of the hinge in an unfolded position of thechassis, such as the position shown in FIG. 1B, whereas FIG. 5B showsthe rear view of the hinge in the unfolded position.

When the top unit 200 is unfolded from the folded position by turningthe top unit 200 in the direction D1, as shown in FIG. 5A, the firstprojection 306 a is located outside the slot 303 a of the control member303, whereby the top unit 200 can be swiveled in the direction D2. Ifthe top unit 200 is further turned in the direction D1, as shown in FIG.5B, the second projection 306 b on the shaft 305 abuts the side wall ofthe control member 303 and thus is stopped thereby. Thus, the maximumangle of the top unit 200 with respect to the bottom unit 100 during theturning of the top unit 200 is determined by the position of the rearside wall of the control member 303.

The top unit 200 is then swiveled from the unfolded position of FIG. 5Bin the direction D2. During the swiveling operation, the turning torquegenerators 309 and 310 generate a pull-in torque on the shaft 305 towarda 180-degree attitude of the top unit 200 with respect to the bottomunit 100, whereby the second projection 306 b on the shaft 305 movesalong the side wall of the control member 303 while abutting thereto.

FIG. 6A shows the hinge at a 90-degree swiveled position wherein the topunit 200 is swiveled from the unfolded position by 90 degrees, The90-degree swiveled position of the cellular phone is shown in FIGS. 6Band 6C, wherein FIG. 6C is taken along line VI—VI in FIG. 6B.

In the 90-degree swiveled position wherein the top unit 200 is swiveledby 90 degrees from the unfolded position, the second projection 306 bstill abuts the side wall of the control member 303, as shown in FIG.6A. The truncated-cone shape of the control member 303 allows the topunit 200 to maintain the 160 degree attitude with respect to the bottomunit 100 in the 90 degree swiveled position of the top unit 200.

When the top unit 200 is further swiveled to reach a 180 degree swiveledposition, the second projection 306 b reaches the slot 303 a of thecontrol member 303 and is received therein, whereby the top unit 200cannot be swiveled any more in the direction D2. In the 180-degreeswiveled position, the top unit 200 covers the bottom unit 100, with thedisplay unit 201 of the top unit 200 being exposed at the top of thechassis, as shown in FIG. 1D.

FIGS. 7A to 7D show the control mechanism of the hinge, wherein FIG. 7Ais a top plan view of the control member 303, FIG. 7B is a schematicside view of the hinge in the first folded position, FIG. 7C is anotherschematic side view of the hinge in a slightly unfolded position, andFIG. 7D is another schematic side view of the hinge in an initialfull-unfolded position.

As illustrated in FIG. 7A, the control member 303 is located at theswivel center, and has a slot 303 a on the side wall of the truncatedcone at the front side thereof. The slot 303 a has a width suited forreceiving the tip portion of projection 306 a or 306 b, and a depthdetermined so that the top unit 200 is folded onto the bottom unit 100at an attitude angle of zero degree upon receipt of the projection 303 aor 303 b by the slot 303 a. It is to be noted that the bottom surface ofthe slot 303 a is also slanted, whereby the projection 303 a or 303 bsuitably abuts the bottom surface at the slanted abutment surface of theprojection 303 a or 303 b.

In the folded position of the top unit 200 shown FIG. 7B, the firstprojection 306 a is received in the slot 303 a of the control member303, whereby the top unit 200 is folded onto the bottom unit 100 at anattitude angle of zero degree with respect thereto. The receipt of thefirst projection 306 a by the slot 303 a prohibits the swivel movementof the top unit 200 in the direction D2, thereby preventing rubbing orfriction between the main surfaces of the top unit 200 and the bottomunit 100 in the folded position. In addition, an unintended swivelmovement of the top unit 200 by an external force is also avoided, theexternal force being applied to any of the top unit 200 and the bottomunit 100.

In the slightly unfolded position of the top unit 200 shown in FIG. 7C,for example, at an attitude angle of several degrees, the firstprojection 306 a on the shaft 305 is located outside the slot 303 a,whereby the top unit 200 can be swiveled in the direction D2 by 360degrees. In other words, the top unit 200 cannot be swiveled unless thetop unit 200 is unfolded or lifted with respect to the bottom unit 100via the hinge 300.

In the initial full-unfolded position of the top unit 200 shown in FIG.7D, the second projection 306 b on the shaft 305 abuts the rear sidewall of the control member 303 and is stopped thereby. This determinesthe attitude angle of the iniital full-unfolded position between the topunit 200 and the bottom unit 100. The subsequent swivel movement of thetop unit 200 is not iterated herein for avoiding a duplication.

Second Embodiment

FIGS. 8A to 8D illustrate the control member 303, a first foldedposition, an unfolded position and a second folded position,respectively, of the hinge used in a data processing apparatus accordingto a second embodiment of the present invention. The second embodimentis similar to the first embodiment except for the configuration of thecontrol member.

As shown in FIG. 8A, the control member 403 in the present embodiment islocated at the swivel center of the top unit 200, and has a shape ofpartial truncated cone, wherein a front portion of a truncated cone iscut off along a plane passing chords of the top and bottom circles ofthe truncated cone. Thus, the control member 403 has a trapezoid plane403 a at the front side thereof. The location of the trapezoid plane 403a is determined so that the top unit 200 is folded onto the bottom unit100 at an attitude angle of zero degree with respect thereto uponabutment of projection 306 a or 306 b on the shaft 305 to the trapezoidplane 403 a. It is to be noted that the trapezoid plane 403 a isslightly slanted corresponding to the slanted abutment surface ofprojection 306 a or 306 b.

As illustrated in FIG. 8B, in the hinge during the folded position, thefirst projection 306 a on the shaft 305 abuts the trapezoid plane 403 aof the controlling projection 403, whereby the top unit 200 is foldedonto the bottom unit 100 at an attitude angle of zero degrees withrespect thereto. The first projection 306 a abutting the trapezoid plane403 a prevents the top unit 200 from swiveling in the direction D2,thereby preventing rubbing or friction between the main surfaces of thetop unit 200 and the bottom unit 100 in the folded position. Inaddition, an unintended swivel movement of the top unit 200 by anexternal force is also avoided.

When the top unit 200 is slightly unfolded from the bottom unit 100, thefirst projection 306 a is released from the trapezoid plane 403 a of thecontrolling projection 403, whereby the top unit 200 can be swiveled inthe direction D2 within the range defined by the trapezoid plane 403 a.In other words, the top unit 200 cannot be swiveled without unfolding orraising the top unit 200 with respect to the bottom unit 100 via thehinge.

After the top unit 200 is further unfolded or raised, as shown in FIG.8C, the second projection 306 b abuts the rear side wall of the controlmember 403 and thus is stopped thereby, whereby the attitude anglebetween the top unit 200 and the bottom unit in the unfolded position isdefined at 160 degrees in the present embodiment.

When the top unit 200 is swiveled in the direction D2 from the unfoldedposition of FIG. 8C, the second projection 306 b moves along the sidewall of the control member while abutting thereto. After the top unit200 is swiveled by 90 degrees, the second projection 306 b on the shaft305 is located on the lateral side of the control member 403. In thepresent embodiment, the control member 403 having a truncated conicalshape except for the trapezoid plane 403 a maintains the initialattitude angle between the top unit 200 and the bottom unit 100 afterthe 90 degree swiveling movement of the top unit 200.

When the top unit 200 is further swiveled in the direction D2, thesecond projection 306 b abuts the trapezoid 403 a of the control member403. In this position, the top unit 200 is folded onto the bottom unit100 at an attitude angle of 180 degrees with respect to the bottom unit100, with the display unit on the top unit 200 being exposed at the topof the chassis. The trapezoid plane 403 a in association with the secondprojection 306 b prevents the swiveling of the top unit 200 at the180-degree swiveled position.

Third Embodiment

FIGS. 9A to 9D illustrate, similarly to FIGS. 8A to 8D, respectively,the hinge used in a data processing apparatus according to a thirdembodiment of the present invention. The third embodiment is similar tothe first embodiment except for the configuration of control member inthe hinge.

As illustrated in FIG. 9A, the control member 503 in the hinge isdisposed at the location deviated from the swivel axis of the top unit200 toward the rear side, and has a configuration wherein the slantedangle of the side wall of the truncated cone is moderately changed alongthe circumferential direction. More specifically, the control member 503has a maximum slanted angle at the front side 503 a and a minimumslanted angle at the rear side 503 b, wherein the slanted angleincreases from the rear side toward the front side as viewed in thecircumferential direction. The maximum slanted angle at the front sideis determined so that the projection 306 a or 306 b abutting the sidewall at the front side allows the top unit 200 to be folded at anattitude angle of zero degree with respect to the bottom unit 100. Onthe other hand, the minimum slanted angle at the rear side is determinedso that the second projection 306 b abutting the side wall at the rearside allows the top unit 200 to be unfolded to an attitude angle of 160degrees with respect to the bottom unit 100.

As illustrated in the folded position shown in FIG. 9B, the firstprojection 306 a abuts the front side 503 a of the control member 503,whereby the top unit 200 is folded at an attitude angle of zero degreewith respect to the bottom unit 100. A slot, such as the slot 303 a inthe first embodiment, may be formed on the front side 503 a of thecontrol member 503 for preventing the top unit 200 from swiveling in thedirection D2.

When the top unit 200 is unfolded, as shown in FIG. 9C, the secondprojection 306 b abuts the rear side 503 b of the control member 503 andis stopped thereby, whereby the attitude angle of the top unit 200 withrespect to the bottom unit 100 is determined at 160 degrees.

When the top unit 200 is swiveled in the direction D2 from the unfoldedposition of FIG. 9C, the second projection 306 b moves along the sidewall of the control member 503 while abutting thereto. The configurationwherein the slanted angle of the control member 503 increases from therear side 503 b toward the front side 503 a allows the attitude angle ofthe top unit 200 with respect to the bottom unit 100 to increase from160 degrees during the swiveling.

After the top unit 200 is further swiveled to allow the secondprojection 306 b to reach the front side 503 a, as shown in FIG. 9D, thetop unit 200 is folded onto the bottom unit 100 at an attitude angle of180 degrees, with the display unit 210 being exposed on the top of thechassis.

The contour of the control member 503 in the present embodiment maycause a higher load compared, to the case of the truncated cone in thefirst embodiment during the swivel movement of the top unit 200 in thedirection D2. This higher load can be lowered by a configuration whereinthe abutment surfaces of the projections 306 a and 306 b matches withthe side wall of the control member 503, as will be described later withreference to FIG. 12.

Fourth Embodiment

FIGS. 10A to 10D illustrate, similarly to FIGS. 8A to 8D, the hinge in afourth embodiment of the present invention. The present embodiment issimilar to the first embodiment except for the configuration of thecontrol member in the hinge. FIG. 11A shows the cellular phone of thepresent embodiment at a swiveled angle of 90 degrees for the top unit200 with respect to the bottom unit 100, and FIG. 11B is a sectionalview taken along line XI—XI in FIG. 11A.

As shown in FIG. 10A, the control member 603 in the present embodimentis such that a truncated cone is prolonged in the posterior direction ofthe cellular phone, wherein the slanted angle of the prolonged truncatedcone is changed among the front, rear and lateral sides thereof. Morespecifically, the slanted angle of the control member 603 is maximum atthe front side 603 a and lateral sides 603 c, and minimum at the rearside 603 b, with the slanted angle of the intermediate side beingmoderately changed. The slanted angle of the front side 603 a andlateral sides 603 c is designed such that the top unit 200 is foldedonto the bottom unit 100 at an attitude angle of zero degree uponabutment of the projection 306 a or 306 b to the control member 603. Onthe other hand, the slanted angle at the rear side 603 b is designedsuch that the top unit 200 is unfolded at an attitude angle of 160degrees with respect to the bottom unit 100 upon abutment of the secondprojection 306 b to the control member 603.

As illustrated in the folded position of FIG. 10B, the first projection306 a abuts the front side 603 a of the control member 603, whereby thetop unit 200 is folded onto the bottom unit 100 at an attitude angle ofzero degree therebetween. A slot, such as the slot 303 a in the firstembodiment, may be provided on the control member 603.

When the top unit 200 is unfolded from the folded position of FIG. 10B,the second projection 306 b on the shaft 305 abuts the rear side 603 bof the control member, as shown in FIG. 10C. This, allows the top unit200 to be stopped at an attitude angle of 160 degrees with respect tothe bottom unit 100.

When the top unit 200 is swiveled in the direction D2 from the unfoldedposition of FIG. 10C, the second projection 306 b moves along the sidewall of the control member 603 while abutting thereto. Since the controlmember 603 has a slanted angle profile wherein the slanted angleincreases from the rear side 603 b toward the lateral side 603 c, theattitude angle of the top unit 200 with respect to the bottom unit 100defined by the second projection 306 b increases when the top unit 200is swiveled from the unfolded position. Thus, the attitude angle of thetop unit 200 assumes 180 degrees upon abutment of the second projection306 b to the lateral side 603 c of the control member 603, as shown inFIGS. 11A and 11B. At this attitude of the cellular phone, the user canoperate the keyboard and watch the display unit comfortably.

When the top unit 200 is further swiveled from the 90 degree swiveledposition of FIGS. 11A and 11B, the second projection 306 b abuts thefront side 603 a of the control member 603, as shown in FIG. 10D,whereby the top unit 200 is folded onto the bottom unit 100 at anattitude angle of 180 degrees.

Again in the present embodiment, the abutment surfaces of theprojections 306 a and 306 b correspond to the contour of the side wallof the control member 603, as will be described later.

As illustrated in FIGS. 11A and 11B, the top unit 200 is parallel to thebottom unit 100 upon a 90-degree swiveled position of the top unit 200in the present embodiment. This attitude is convenient for operating acamera unit in the case where the lens (or opening) 701 of the cameraunit is provided on the top surface of the top unit 200.

As illustrated in FIGS. 11A and 11B, the display unit 201 isconveniently used as a monitor for operating the camera unit having thelens 701. In the illustrated attitude of the cellular phone, since thetop unit 200 is parallel to the bottom unit 100, the visual line of theuser observing the monitor 201 is conveniently parallel to the visualaxis 703 of the lens 701.

As described in connection with the third and fourth embodiments, theslanted angle profile, wherein the slanted angle of the control member503 or 603 is changed along with the swivel movement of the top unit200, controls the attitude angle of the top unit 200 during the swivelmovement of the top unit 200 for the convenience of handling thecellular phone.

In other words, the swivel movement of the top unit 200 in the directionD2 is converted to the turning movement of the top unit 200 in thedirection D1 by the slanted angle profile of the control member 503 or603. This means that the combination of the projections on the shaft andthe control member configures a cam assembly.

Referring to FIG. 12, there is shown a contact angle of the projection306 b, exemplifying the relationship between the projections 306 a and306 b on the shaft 305 and the control member 503 (603) in the third(fourth) embodiment.

In view that the slanted angle profile, wherein the slanted angle of thecontrol member 503 changes along with the swiveled angle of the top unit200, increases the mechanical load during the swivel movement of the topunit 200, the abutment surfaces 801 and 802 of the projections 306 a and306 b as well as the tangential line of the side wall of the controlmember 503 is designed to align with the radial direction of the shaft305, as illustrated in FIG. 12.

In the example of FIG. 12, the abutment surface 802 is aligned with theradial direction of the shaft 305, and other abutment surfaces 803 and804 illustrated by imaginary lines are also aligned with the radialdirection of the shaft 305.

The configuration shown in FIG. 12 provides a highest mechanicalefficiency in the swiveling movement of the top unit 200 with respect tothe bottom unit 100 while allowing the first or second projection 306 aor 306 b to abut the side wall of the control member 503. Thisconfiguration also provides an improvement of the mechanical strength ofthe components, whereby deformation of the first and second projections306 a and 306 b as well as the control member 503 can be prevented, suchas upon abutment of the second projection 306 b to the control member503 during an unfolding movement of the top unit 200.

In the above embodiment, the hinge of the present invention is used inthe cellular phone; however, the hinge of the present invention can beused in any of the fold-type data processing apparatus.

Since the above embodiments are described only for examples, the presentinvention is not limited to the above embodiments and variousmodifications or alterations can be easily made therefrom by thoseskilled in the art without departing from the scope of the presentinvention.

1. A fold-type data processing apparatus comprising a first unit, asecond unit and a hinge mechanism for coupling together said first unitand said second unit and allowing said second unit to turn and swivelwith respect to said first unit via said hinge mechanism, said hingemechanism comprising: a shaft having a first axis mounting thereon saidsecond unit for allowing said second unit to be turned around said firstaxis; a swiveling member fixed onto said first unit and allowing saidshaft and said second unit to swivel with respect to said first unitaround a second axis perpendicular to said first axis; at least oneprojection member fixed onto said shaft; and a control member fixed ontosaid first unit and having a side wall, at least a portion of said sidewall having a slanted surface, wherein said projection member abuts saidside wall to restrict a movement of said second unit, and wherein saidprojection member is allowed to swivel with respect to said controlmember when said second unit is in a first position such that saidsecond unit turns around said second axis.
 2. The fold-type dataprocessing apparatus according to claim 1, wherein said control memberis of a trapezoid in a longitudinal sectional view thereof.
 3. Thefold-type data processing apparatus according to claim 1, wherein saidprojection member abuts said side wall in an abutment plane aligned witha radial direction of said shaft.
 4. The fold-type data processingapparatus according to claim 1, wherein said projection member is ableto swivel with respect to said control member when said second unit isin said first position and is restricted from swiveling with respect tosaid control member when said second unit is in a second position. 5.The fold-type data processing apparatus according to claim 4, whereinsaid control member includes a slotted portion, and said projectionmember is inserted into said slotted portion when said second unit is insaid second position.
 6. The fold-type data processing apparatusaccording to claim 1, wherein said control member comprises a swivelstopper formed on said side wall for preventing said second unit fromswiveling around said second axis when said second unit is in a secondposition.
 7. The fold-type data processing apparatus according to claim6, wherein said swivel stopper is a slot for receiving at least aportion of said projection member.
 8. The fold-type data processingapparatus according to claim 6, wherein said swivel stopper is a planeformed on said side wall for abutting said projection member.
 9. Thefold-type data processing apparatus according to claim 1, wherein saidprojection member abuts said side wall of said control member torestrict an attitude angle between said first unit and said second unitupon said turning of said second unit around said shaft.
 10. Thefold-type data processing apparatus according to claim 9, wherein saidattitude angle is restricted at a specified angle between 160 degreesand 170 degrees upon said turning of said second unit.
 11. The fold-typedata processing apparatus according to claim 9, wherein said projectionmember moves along said side wall of said control member while abuttingthereto when said second unit is swiveled with respect to said firstunit, thereby restricting said attitude angle.
 12. The fold-type dataprocessing apparatus according to claim 11, wherein said attitude angleis changed between said specified angle and 180 degrees when said secondunit is swiveled with respect to said first unit.
 13. The fold-type dataprocessing apparatus according to claim 12, wherein said attitude angleis changed from said specified angle to said 180 degrees, when saidsecond unit is swiveled with respect to said first unit by a swiveledangle of 180 degrees after turning of said second unit from a foldedposition.
 14. The fold-type data processing apparatus according to claim12, wherein said attitude angle is changed from said specified angle tosaid 180 degrees, when said second unit is swiveled with respect to saidfirst unit by a swiveled angle of 90 degrees after turning of saidsecond unit from a folded position.
 15. The fold-type data processingapparatus according to claim 1, wherein said second unit mounts thereona display unit, said at least one projection member includes first andsecond projection members apart from one another in a turning directionof said second unit, said first projection member abuts a first portionof said control member when said second unit is folded onto said firstunit with said display unit opposing said second unit, said secondprojection member abuts a second portion of said control member whensaid second unit is unfolded from said first unit by turning.
 16. Thefold-type data processing apparatus according to claim 15, wherein saidfirst portion includes a swivel stopper for restricting a swivelmovement of said second unit upon abutment of said first or secondprojection member to said first portion of said control member.
 17. Thefold-type data processing apparatus according to claim 15, wherein eachof said first and second projection members has an abutment surfacehaving a tangent line extending in a radial direction of said shaft, andsaid side wall of said control member has a tangential line extending insaid radial direction.